Pressurized metered dose inhalers and method of manufacture

ABSTRACT

The invention relates to a method for the manufacture of a pressurized Metered Dose Inhaler (pMDI) and components for use in the method, in particular, a pMDI compatible tablet (i.e. one that is able to be dispersed or disintegrates within a liquid phase, such as a propellant, used in a pMDI formulation) which contains at least one active pharmaceutical ingredient (API) and, potentially, one or more excipients.

This application is a continuation patent application claiming priorityfrom U.S. patent application Ser. No. 15/117,549 filed on Aug. 9, 2016which is the national stage of international patent application no.PCT/GB2015/050390 filed on Feb. 12, 2015 which in turn claims priorityfrom British Patent Application No. 1402513.4 filed on Feb. 13, 2014,the disclosures of which are incorporated herein by reference in theirentirety.

TECHNICAL FIELD

The invention relates to a method for the manufacture of a pressurizedMetered Dose Inhaler (pMDI) and components for use in said method, inparticular, a pMDI compatible tablet (i.e. one that is able to bedispersed or disintegrates within a liquid phase, such as a propellant,used in a pMDI formulation) which contains at least one activepharmaceutical ingredient (API) and, optionally, one or more excipients.

BACKGROUND

The key component of a pMDI is a canister which contains a liquid phasesuch as a propellant (which may also include low volatility co-solvents)in which the active pharmaceutical ingredient (API) is present either insolution or suspended in the form of micronised particles (eithermicrometers or nanometers in diameter). The propellants commonly usedare hydrofluoroalkanes (HFA) such as HFA 134a (tetrafluorethane) and HFA227ea (heptafluoropropane). Solvents of relatively low volatility e.g.ethanol, and/or formulation modifiers e.g. glycerol are often includedin the formulations to enhance API solubility in the propellant to yielda solution formulation, or to modify the aerosol properties of theformulation (1, 2). Many APIs or drugs however do not have sufficientsolubility in HFA/solvent blends or, alternatively, are not chemicallystable in solution and as a result suspension systems must beformulated. Low volatility solvents are also used in suspension systemsto promote the solubility of surfactants which function to stabilize thesuspension of micronised API particles. pMDIs are the most commonly useddelivery systems for treating asthma, chronic obstructive pulmonarydisease (COPD) and other diseases of the respiratory tract and foradministering to the buccal cavity.

The pMDI container (usually in the form of an aluminium canister whichmay be anodized or coated, or a stainless steel canister) provides areservoir for doses, typically between 60 to 200 metered doses, whichwill usually provide one months' medication for a patient, or mayprovide one dose of a rescue medication. The doses are dispensed via ametering valve which is crimped onto the pMDI container. Typical meteredvolumes range from 25-75 μL. In use, the canister is housed in a plasticactuator which enables the metered volume to be delivered as an aerosolto the patient via the actuator mouthpiece.

Manufacturing processes fall broadly into two categories; single stagefilling or two-stage filling. In the former process the formulationconsists of an API, or combination of APIs, either suspended ordissolved in the propellant (which may also contain a small fraction oflow volatility solvent e.g. ethanol and an appropriate surfactant).During manufacture the propellant is maintained as a liquid by the useof high pressure or low temperature. In the case of a suspensionformulation the micronised API (ideal particle size in the region of3μm) must be homogenously dispersed during all stages of manufacture andcare is taken to ensure that the particulate API does not settle oraggregate in any of the vessels, homogenisers, pumps, machinery orfilling lines required to dispense the formulation into the pMDIcontainer. Very often it is necessary to continuously homogenise andrecirculate the liquefied suspension formulation to ensure uniformdispersion of the API. During filling care must be taken to ensureaccurate and reproducible filling of API/propellant into the pMDIcontainer. Filling may be performed into open canisters followed bycrimping on of the metering valve (cold filling) or alternatively theAPI/propellant may be dispensed into the sealed cans via the meteringvalve (pressure filling).

For two-stage filling, the “first stage” typically involves dispensingof a concentrated suspension or solution of API in a low volatilitysolvent or suspending medium e.g. ethanol (with or without appropriatesurfactant) into an open pMDI container followed by crimping on of themetering valve. Care must be taken to ensure that the filling proceduredelivers an accurate and reproducible amount of API solution orsuspension into every container and very often it is necessary tocontinuously homogenise and recirculate formulations to ensure uniformdispersion of the API. The “second stage” involves the addition of anaccurate and reproducible amount of propellant.

One of the inventors has previously shown (3) that effectiveformulations for suspension pMDIs may include a (second) particulatematerial (excipient) in addition to the micronised API within the liquidpropellant. The particle size distribution of the second particulate ispredominantly greater than that of the micronised API. The particulatecarrier and the API may be present as either a simple admixture or withsome or all of the smaller API particles interacting with the largerparticles of the second particulate material.

However, in contrast to this earlier work it is herein disclosed a newpMDI formulation and a process for the manufacturing of a pMDI, whereinthe API is added to a canister in tablet form prior to the processes of(in the order consistent with pressure or low temperature filling)crimping the metering valve on the canister and filling with propellant.

There is therefore disclosed herein the production of a pMDI using atleast one API(s) in the form of a tablet wherein the API is either onits own or with at least one excipient.

SUMMARY

According to a first aspect of the invention there is provided a methodfor the manufacture of a pMDI comprising:

-   -   i) compressing a selected amount of:        -   at least one particulate active pharmaceutical ingredient            (API) into a tablet;    -   ii) placing said tablet into a canister;    -   iii) fixedly attaching a dispensing valve to said canister; and    -   iv) dispensing liquid phase into said canister.

Whilst the above method is presented as a single process, there may bean interval following steps i), ii) or iii. Moreover step iv) may occurbefore step iii) as appropriate for low temperature filling. Thus thevarious steps may be undertaken as part of a single sequentialmanufacturing process or the various steps may be undertaken,sequentially, but after time intervals typically determined byconvenience and also, possibly, the steps may be undertaken in differentenvironments. Indeed, it is the devising of the invention that lendsitself to the fragmentation (discontinuity) of the manufacturing processwhereby component parts of pMDIs can be manufactured.

Reference herein to tablet refers to a compacted dosage form of the API,with or without suitable excipients/diluents, produced by compression orcompaction of same.

As will be appreciated by those skilled in the art, said tablet may varyin shape, size, weight and density, whilst still achieving the desiredtechnical effect as disclosed herein.

The invention offers a number of potential advantages over the pMDImanufacturing processes described in the background, these advantagesare described within the invention and claims below.

In a preferred embodiment of the invention said API is micronised.

In yet a further preferred embodiment of the invention said API issoluble in a liquid phase. Hereinafter, liquid phase shall include butis not limited to propellant such as HFA propellant (which may contain ablend of HFA propellants, and optionally a proportion of suitablehydrocarbon(s) and/or low volatility co-solvents, and/or formulationmodifiers). Preferably said soluble APIs include but are not limited tobeclometasone dipropionate or ciclesonide or formoterol fumaratedihydrate or ipratropium, or flunisolide hemihydrate.

Alternatively, or additionally, said API is insoluble in the liquidphase. Preferably said insoluble APIs are selected from but are notlimited to the group comprising: salbutamol sulphate, fluticasonepropionate or salmeterol xinafoate.

In addition, either in solution or suspension form, the following APIscould be formulated with this invention: bronchodilators, e.g.,indacaterol maleate, olodaterol, vilanterol, ephedrine, adrenaline,fenoterol, isoprenaline, metaproterenol, phenylephrine,phenylpropanolamine, pirbuterol, reproterol, rimiterol, terbutaline,isoetharine, tulobuterol; anti-inflammatories, e.g. budesonide,rofleponide, mometasone furoate or triamcinolone acetonideanticholinergics, e.g., tiotropium, aclidinium bromide, glycopyrroniumbromide, umeclidinium, atropine or oxitropium; xanthines, e.g.theophylline.

Further examples of appropriate APIs may additionally be selected from,for example, analgesics, e.g. codeine, dihydromorphine, ergotamine,fentanyl or morphine; anginal preparations, e.g., diltiazem;antiallergics, e.g., cromoglycate, ketotifen or nedocromil;anti-infectives e.g., cephalosporins, penicillins, streptomycin,sulphonamides, tetracyclines and pentamidine; antihistamines, e.g.,methapyrilene; antitussives, e.g., noscapine; diuretics, e.g.,amiloride; hormones. e.g., cortisone, hydrocortisone or prednisolone:therapeutic proteins and peptides. e.g., insulin or glucagon,calcitonin, growth hormone, lutenising hormone release hormone (LHRH),leuprolide, oxytocin.

It will be clear to a person skilled in the art that, where appropriate,the APIs may be used in the form of salts, (e.g., as alkali metal oramine salts or as acid addition salts) or as esters (e.g., lower alkylesters) or as solvates (e.g., hydrates) to optimise the activity and/orstability of the API.

In yet a further preferred embodiment of the invention, a disintegrant(something that disintegrates or disperses in the liquid phase) and/orexcipient is compressed into said tablet.

In yet a further preferred embodiment of the invention said liquid phasecomprises a low volatility solvent and/or a surfactant.

In a preferred embodiment of the invention a plurality of APIs may beused in the above method. Ideally, each will be selected having regardto the nature of the condition to be treated. More preferably, at leastone or a plurality of APIs is/are soluble in the liquid phase or atleast one or a plurality of APIs are insoluble in the liquid phase.

Alternatively, at least one API soluble in the liquid phase and at leastone API insoluble in the liquid phase is used in the above method. Aswill be appreciated by those skilled in the art, advantageously, thispermits manufacture of a pMDI having a combination of disparate APIs(soluble and insoluble) to be incorporated into the same canister, whichconventionally has been problematical due to their different chemicalstates. Further, without wishing to be bound by theory, we consider thatas the compressed soluble API will more readily dissolve and disperse,homogeneous dispersal of the insoluble API will occur more readily.

In a further preferred embodiment of the invention said disintegrant isselected on the basis that it has sufficient solubility in the liquidphase such that when exposed to same, the disintegrant dissolves andgoes into solution resulting in the structure of the tablet breakingdown and any insoluble API and any insoluble excipient (if included) ishomogeneously dispersed in the liquid phase (which may contain a lowvolatility solvent and/or modifier e.g. surfactant). Alternatively ifthe API is sufficiently soluble in the liquid phase it may be dissolvedalong with the disintegrant and any insoluble excipient will then bedispersed in the liquid phase.

Accordingly, reference herein to a disintegrant is to a material thatcan be compressed into a tablet form with said API, and (when present)an excipient, and which is soluble in said liquid phase.

Those skilled in the art will therefore appreciate than its broadestteaching, the invention concerns the provision of one or moreparticulate active pharmaceutical ingredients (APIs) compressed into atablet and used to work the afore method. More typically, the inventionis worked using at least one API and a disintegrant and/or excipient.

Most preferably, said disintegrant is included in said tablet and isselected from the group comprising: menthol, propylene glycol (PG),polyvinylpolypyrrolidone (PVP), polyethylene glycol (PEG), glycerol,sodium bicarbonate, citric acid and non-toxic essential oils.

In yet a further preferred embodiment, the invention is worked using atleast one API, a disintegrant and an excipient.

In yet a further preferred embodiment of the invention the method ofpart i) further includes compressing a lubricant/glidant such as, forexample, magnesium stearate into said tablet.

Most preferably, said disintegrant is mixed with or coated onto said oneor more API's then this material is compressed into said tablet.Additionally, or alternatively, said disintegrant is mixed with orcoated onto said excipient (when present) then this material iscompressed into said tablet with said API. Said tablet is then exposedto said liquid phase in which it dissolves and/or is dispersed leaving asolution or dispersion of API or API/excipient and solubiliseddisintegrant.

Most preferably still, said disintegrant is a non-toxic essential oili.e. it is an oil extracted from plant material or its correspondingsynthetic counterpart such as the oil extract from allspice, amber,anise, arnica, basil, bay bergamot, rose wood, cajeput, calendula,camphor, caraway, cardamom, carrot, cedar, celery, chamomile, cinnamon,citronella, clary sage, coriander, cumin, cypress, eucalyptus, fennel,fir, frankincense, garlic, geranium. Ginger, grapefruit, hissop,jasmine, jojoba, juniper, lavender, lemon, lemongrass, lime marjoram,menthol, mugwort, mullein, myrrh, neroli, nutmeg, orange, oregano,patchouly, pepper, peppermint, pine, rose, rosehip, rosemary, sage,sandalwood, spearmint, tangerine, tea tree, thyme, vanilla, vetivert,witch hazel, and ylang ylang. Notably, these essential oils show goodsolubility in HFA propellants (4). Preferably said essential oils areused at a concentration range less than 1% to 20% w/w in liquidpropellant.

In a preferred embodiment of the invention said excipient is aparticulate carrier material. Preferred materials include those commonlyused in pharmaceutical drug delivery systems, e.g. carbohydratesincluding sugars, mono-, di-, tri-, oligo-, polysaccharides and anyphysiologically acceptable derivatives, salts, solvates thereof and anymixtures thereof e.g. lactose, spray dried lactose. Other suitableparticulate carrier materials include amino acids, di-, tri-, oligo-,polypeptides, proteins and any physiologically acceptable derivatives,salts, solvates thereof and mixtures thereof, e.g. leucine.Advantageously, because of their relatively large particle size (i.e.range 15 μm-200 μm) these carrier particles are not likely to penetrateinto the lungs during use. Thus, preferred particulate carrier materialshave a particle size in the range 15 μm-200 μm.

More preferably, said excipient is coated with a disintegrant selectedfrom the group comprising: menthol, propylene glycol (PG),polyvinylpolypyrrolidone (PVP), polyethylene glycol (PEG), glycerol,sodium bicarbonate, citric acid and a non-toxic essential oil.

We have discovered that upon addition of the liquid phase to thecanister the tablet, and any disintegrant and/or excipient, may beeffectively disintegrated by the energy imparted as the liquid phasefills the canister. In some instances, agitation or sonication may beadditionally required to completely effect disintegration or dispersion.After tablet disintegration or dispersion the API and any disintegrantand/or excipient/particulate carrier exist dissolved/suspended in theliquid phase. Thus the amount of disintegrant added to the tablet isideally the minimum required to ensure the necessary dispersion of thetablet upon contact with the liquid phase.

In a preferred method the propellant is a hydrofluorcarbon and mixturesor blends thereof. Preferably said propellant is a hydrofluoroalkane(HFA) such as e.g. HFA 134a (tetrafluorethane) or HFA 227ea(heptafluoropropane) and or blends mixtures thereof. Preferably saidpropellant is a hydrofluoroolefin and mixtures or blends thereof.

In a further preferred embodiment of the invention said aforepropellants also contain low volatility solvents e.g. ethanol and/orappropriate surfactants and may also contain appropriate proportions ofselected hydrocarbons and/or formulation modifiers.

In a further preferred method of the invention said propellant comprisesat least 80% w/w and up to 99.99% w/w, more preferably at least 90% w/wand up to 99.9% w/w).

As mentioned, we have also discovered that having the API provided as atablet gives flexibility to the manufacture of the finished product.This is because the tablet formulations, if stored appropriately,possess pharmaceutical stability so that dispensing same into canisterscould, if necessary, be performed a significant length of time afterpreparing the tablets. Thus the tablets could be dispensed intocanisters and valves fixedly attached, typically by crimping, at onefacility followed by the addition of the propellant at another facility.The final manufacturing site would not therefore require costly andcomplex pressure mixing vessels for dispensing pressurized suspensions.Moreover, exposure to open sources of the API would be restricted to onesite.

Other advantages that flow from the above manufacturing process arisefrom the avoidance of having to undertake real time API analyticalin-process controls to determine the quantity of API dispensed into eachcontainer. Indeed, this measuring could be performed during tabletmanufacture using well establish methodologies. Furthermore, there wouldbe no requirement to compensate for propellant evaporation in pressurevessels during the filling process in order to maintain the correctconcentration of API and ensure that accurate and reproducible fillingof API in to the canisters. Another key advantage stems from theavoidance of having to constantly monitor the homogeneity of a liquefieddispersion of API in propellant during manufacture and filling ofsuspensions.

Particularly preferred disintegrants, ideally used as coatings, arementhol and propylene glycol (PG).

Most expressly preferred excipients are particulate carrier materialshaving a size range between range 15 μm-200 μm coated with disintegrantssuch as menthol or PG. Most ideally, said particulate carrier is lactoseor leucine and it is, ideally, coated with menthol or PG.

According to a second aspect of the invention there is provided a tabletfor use in the manufacture of a pMDI comprising:

-   -   i) a selected amount of at least one active particulate        pharmaceutical ingredient (API);    -   ii) a disintegrant that is soluble in a liquid phase; and    -   iii) optionally, at least one excipient.

In yet a further preferred embodiment of the invention said API is amicronised API.

In yet a further preferred embodiment of the invention said API issoluble in the liquid phase.

Alternatively, or additionally, said API is insoluble in the liquidphase.

In yet a further preferred embodiment of the invention said tabletcomprises a plurality of APIs. Preferably, said tablet comprises aplurality of APIs soluble in the liquid phase or a plurality of APIsinsoluble in the liquid phase.

Alternatively, said tablet comprises at least one, or a plurality of,API(s) soluble in the liquid phase and at least one, or a plurality ofAPI(s) insoluble in the liquid phase.

More preferably still, said API is a respiratory therapeutic. Yet morepreferably, said therapeutic is for treating one or more of thefollowing diseases or conditions locally in the lungs: asthma,bronchitis, COPD, chest infections. Additionally the API might beselected for its systemic action within the body e.g. for acute painrelief, migraine, disorders of hormonal imbalance and cardiovasculardisease. The API or combination of APIs of the invention may also beadministered orally or intra-nasally for local treatment of disease orfor systemic action within the body.

In a preferred embodiment of the invention said excipient is aparticulate carrier material. Preferred materials include those commonlyused in pharmaceutical drug delivery systems, e.g. carbohydratesincluding sugars, mono-, di-, tri-, oligo-, polysaccharides and anyphysiologically acceptable derivatives, salts, solvates thereof and anymixtures thereof e.g. lactose, spray dried lactose. Other suitableparticulate carrier materials include amino acids, di-, tri-, oligo-,polypeptides, proteins and any physiologically acceptable derivatives,salts, solvates thereof and mixtures thereof, e.g. leucine.Advantageously, because of their relatively large particle size (i.e.range 15 μm-200 μm) these carrier particles are not likely to penetrateinto the lungs during use. Thus, preferred particulate carrier materialshave a particle size in the range 15 μm-200 μm.

Thus, in yet a further preferred embodiment of the invention saidexcipient has a particle size in the range 15 μm-200 μm.

More preferably, said disintegrant is selected from the groupcomprising: menthol, propylene glycol (PG), polyvinylpolypyrrolidone(PVP), polyethylene glycol (PEG), glycerol, sodium bicarbonate, citricacid and a non-toxic essential oil.

More preferably, said excipient is coated with a disintegrant selectedfrom the group comprising: menthol, propylene glycol (PG),polyvinylpolypyrrolidone (PVP), polyethylene glycol (PEG), glycerol,sodium bicarbonate, citric acid and non-toxic essential oils.

Particularly preferred coatings are menthol and propylene glycol (PG).

Most expressly preferred excipients are particulate carrier materialshaving a size range between range 15 μm-200 μm coated with menthol orPG. Most ideally, said particulate carrier is lactose or leucine and itis, ideally, coated with menthol or PG.

More preferably still, said tablet further comprises a lubricant such assodium lauryl sulphate and/or magnesium stearate.

Throughout the description and claims of this specification, the words“comprise” and “contain” and variations of the words, for example“comprising” and “comprises”, mean “including but not limited to” and donot exclude other moieties, additives, components, integers or steps.Throughout the description and claims of this specification, thesingular encompasses the plural unless the context otherwise requires.In particular, where the indefinite article is used, the specificationis to be understood as contemplating plurality as well as singularity,unless the context requires otherwise.

All references, including any patent or patent application, cited inthis specification are hereby incorporated by reference. No admission ismade that any reference constitutes prior art. Further, no admission ismade that any of the prior art constitutes part of the common generalknowledge in the art.

Preferred features of each aspect of the invention may be as describedin connection with any of the other aspects.

Other features of the present invention will become apparent from thefollowing examples. Generally speaking, the invention extends to anynovel one, or any novel combination, of the features disclosed in thisspecification (including the accompanying claims and drawings). Thus,features, integers, characteristics, compounds or chemical moietiesdescribed in conjunction with a particular aspect, embodiment or exampleof the invention are to be understood to be applicable to any otheraspect, embodiment or example described herein, unless incompatibletherewith.

Moreover, unless stated otherwise, any feature disclosed herein may bereplaced by an alternative feature serving the same or a similarpurpose.

BRIEF DESCRIPTION OF THE DRAWINGS

The Invention will now be described by way of example only withreference to the Examples below and to the following Figures wherein:

FIG. 1. Distribution Pattern of Recovered Salbutamol Sulphate (SS) (%)from the NGI for Test, Control and Reference Formulations.

Table 1. Solubility Estimates of Glycerol, Tween 80 and PEG 400 in HFA134a.

Table 2. Solubility Estimates (Low Concentration) of Menthol, PVP, PEG6000, PG, Sodium Bicarbonate and Citric Acid in Propellants 227 (*) and134a (#).

Table 3. Solubility Estimates (High Concentration) of Menthol, PVP, andPG in Propellant 227 (*) and 134a (#).

Table 4. Theoretical Concentrations (% w/w) of Additive Coated ontoLactose Samples.

Table 5. Theoretical Concentrations (% w/w) of Salbutamol SulphateCombined with Coated Lactose Samples (excipient and disintegrant) andUncoated Lactose Control.

Table 6. Content Uniformity Data for Coated (excipient and disintegrant)and Uncoated (excipient-Control) SS:Lactose Samples.

Table 7. pMDI Formulations Used for Aerosol Testing. Testformulation=Lactose coated with 1% w/w Menthol Compressed into Tablet(excipient and disintegrant) (*). Control Formulation=Lactose Coatedwith 1% w/w Menthol Uncompressed (excipient and disintegrant) (#).Control Formulation=Uncoated Lactose Uncompressed (§) (excipient only).

Table 8. Summary of Aerosol Characteristics Using 0.35 mm ActuatorOrifice Diameter. Test Formulation=Lactose Coated with 1% w/w MentholCompressed into Tablet (excipient and disintegrant) (*). ControlFormulation=Lactose Coated with 1% w/w Menthol Uncompressed (excipientand disintegrant) (#). Control Formulation=Uncoated Lactose Uncompressed(excipient only)—(§). FPF refers to the fine particle fraction, i.e. the% recovered API with a particle size less than 5 μm. FPD refers to thefine particle mass i.e. the mass of recovered API with a particle sizeless than 5 μm. MMAD refers to the mass median aerodynamic diameter, andGSD refers to the geometric standard deviation of the particle sizedistribution.

Table 9. Summary of Percentage Recovery of SS from the NGI for TestFormulation (*; Lactose Coated with 1% w/w Menthol Compressed intoTablet—excipient and disintegrant), 1% Menthol Control (#; lactosecoated with 1% w/w Menthol uncompressed—excipient and disintegrant),Lactose Control (§; uncoated lactose (excipient) Uncompressed i.e. nodisintegrant) and Reference Formulations (Commercial Ventolin® EvohalerProduct). ECD refers to effective cut-off diameter (μm). MOC refers toMicro orifice collector.

Table 10. Theoretical Concentrations (% w/w) of Salmeterol Xinafoate andFluticasone Propionate Combined with Coated Lactose Samples.

Table 11. Content Uniformity Data for Coated and Un-coated1:8.6(SX)/2.5(FP):Lactose Samples.

Table 12. Content Uniformity Data for Coated and Un-coated1:17.2(SX)/5(FP):Lactose Samples.

Table 13. Salmeterol xinafoate (SX):Fluticasone Propionate (FP)Combination Formulations Containing Lactose used for Aerosol Testing.The ratios (weight:weight) for API:lactose were 1:8.6 for SX and 1:2.5for FP (*Control Formulation=Uncoated Lactose compressed into tablet;#Test Formulation=Lactose coated with 1% w/w Menthol compressed intotablet; ¥Control Formulation=Lactose coated with 1% w/w Mentholuncompressed).

Table 14. Salmeterol xinafoate (SX):Fluticasone Propionate (FP)Combination Formulations Containing Lactose Used for Aerosol Testing.The ratios (weight:weight) for API:lactose were 1:17.2 for SX and 1:5for FP (*Control Formulation=Uncoated Lactose compressed into tablet;#Test Formulation=Lactose coated with 1% w/w Menthol Compressed intoTablet; ¥Control Formulation=Lactose coated with 1% w/w MentholUncompressed).

Table 15. Summary of Aerosol Characteristics of Salmeterol xinafoatefrom a Salmeterol xinafoate (SX):Fluticasone Propionate (FP) CombinationFormulation Containing Lactose. The ratios (weight:weight) forAPI:lactose were 1:8.6 for SX and 1:2.5 for FP. Testing was performedusing a 0.25 mm Actuator Orifice Diameter (Mean values n=3, ±SD).

Table 16. Summary of Aerosol Characteristics of Fluticasone Propionatefrom a Salmeterol xinafoate (SX):Fluticasone Propionate (FP) CombinationFormulation Containing Lactose. The ratios (weight:weight) forAPI:lactose were 1:8.6 for SX and 1:2.5 for FP. Testing was performedusing a 0.25 mm Actuator Orifice Diameter (Mean values n=3, ±SD).

Table 17. Summary of Aerosol Characteristics of Salmeterol xinafoatefrom a Salmeterol Xinafoate (SX):Fluticasone Propionate (FP) CombinationFormulation Containing Lactose. The ratios (weight:weight) forAPI:lactose were 1:17.2 for SX and 1:5 for FP. Testing was performedusing a 0.25 mm Actuator Orifice Diameter (Mean values n=3, ±SD).

Table 18. Summary of Aerosol Characteristics of Fluticasone Propionatefrom a Salmeterol xinafoate (SX):Fluticasone Propionate (FP) CombinationFormulation Containing Lactose. The ratios (weight:weight) forAPI:lactose were 1:17.2 for SX and 1:5 for FP. Testing was performedusing a 0.25 mm Actuator Orifice Diameter (Mean values n=3, ±SD).

Table 19. Summary of Content Uniformity Illustrating Recovery (%) of BDPfrom BDP:Lactose Powder Blends (1:2 and 1:5 weight in weight blends ofBDP and Lactose)

Table 20. Summary of Dose Characteristics of BDP Solution Formulations(0.4 mm actuator orifice diameter). Test tablets were prepared from 1:5BDP:Lactose blends (w/w) with lactose coated with 1% w/w menthol.Control tablets consisted of BDP with uncoated lactose. Additionalcontrols included uncompressed powder formulations and BDP powder aloneadded directly to the HFA 134a:ethanol propellant system.

Table 21. Summary of Dose Characteristics of BDP Solution Formulations(0.25 mm actuator orifice diameter). These are the same test canistersas those described in Tables 24 and 25.

Table 22. Summary of Content Uniformity Illustrating Recovery (%) of BDP& SS from Lactose Powder Blends. The weight:weight (w/w) ratios forAPI:lactose were 1:12 for BDP and 1:5 for Salbutamol Sulphate.

Table 23. Summary of Dose Characteristics of BDP:SS CombinationFormulations (0.25 mm actuator orifice diameter)—BDP Performance. Theweight:weight (w/w) ratios for API:lactose were 1:12 for BDP and 1:5 forSalbutamol Sulphate. Test tablets were prepared from lactose coated with1% w/w menthol. Control tablets consisted of blends of the APIs withuncoated lactose.

Table 24. Summary of Dose Characteristics of BDP:SS CombinationFormulations (0.25 mm actuator orifice diameter)—SS Performance. Theweight:weight (w/w) ratios for API:lactose were 1:12 for BDP and 1:5 forSalbutamol Sulphate. Test tablets were prepared from lactose coated with1% w/w menthol. Control tablets consisted of blends of the APIs withuncoated lactose.

DETAILED DESCRIPTION Materials and Methods Solubility of PotentialDisintegrants

The solubility of some potential disintegrants was estimated by weighingsamples directly into plastic coated glass aerosol bottles or clearpolyethylene terephthalate (PET) aerosol vials, sealing with meteringvalves and filling a known amount of propellant (HFA 134a or HFA 227ea,)directly into the vials using laboratory scale pressure fillingequipment. Samples of glycerol, Tween 80 and PEG (polyethylene glycol)400 were investigated in propellant HFA 134a. Menthol, PVP(polyvinylpolypyrrolidone) (molecular weight 36,000), PEG 6000, PG(propylene glycol), and also citric acid and sodium bicarbonate whichhave potential disintegrant properties were investigated in bothpropellants i.e. HFA 134a and 227.

Coating Lactose Bulk Samples

Separate samples of lactose were coated with either 1% or 5% w/wglycerol, PEG 400 or Tween 80 or with 1% w/w Menthol, PVP (molecularweight 360,000), PEG 6000, or propylene glycol (PG,).

For the 1% w/w samples of disintegrant approximately 0.2 g ofdisintegrant was added to 19.8 g of lactose. For the 5% w/w samples ofdisintegrant approximately 1 g of disintegrant was added to 19 g oflactose.

The disintegrants were dissolved in absolute ethanol and coated onto thelactose as follows. The disintegrant was added to a glass screw cap jar(50 mL) and a small amount of ethanol sufficient to dissolve thedisintegrant was added. Subsequently the lactose was slowly introducedin discrete amounts followed by vigorous shaking of the jar upon eachaddition of lactose. The process was repeated until all the lactose wasadded to the jar and, if necessary (to ensure good wetting anddispersion of the lactose), further ethanol was added. Care was taken toensure that the minimal amount of ethanol was used (enough to alloweffective shaking of the contents and therefore coating of the lactosewith disintegrant). Following shaking the contents were transferred to a2 L Pyrex beaker and dried on stirrer/hotplate and the powdered coatedlactose was recovered and stored in plastic zip-lok bags.

Preliminary Tablet Formulation I—No API

Initial tablet testing was performed using lactose coated with either 1or 5% w/w PEG 400, and either 1% w/w glycerol or Tween 80. Samples oflactose coated with these potential disintegrants were compressed intotablets using a bench top tabletting machine fitted with a caplet punchand die assembly. Tablets were individually manufactured with thecompression force setting no greater than 60 KN. Samples of lactosealone were used as controls. Typical tablet weights were approximately0.4 g.

Test Formulation 1—Salbutamol Sulphate (SS):Coated Lactose

Proof of concept was proved using SS as a model API to blend with thecoated lactose. Micronised SS was blended with coated lactose so thatthe final product contained approximately 5% w/w SS. Batch sizes wereapproximately 9.45 g total powder. Samples of the treated lactose wereblended with the SS by passing through a 90 μm test sieve andtransferred to a glass mortar. Thereafter the remaining coated lactosewas added to the mortar so as to ensure geometric dilution of the mortarcontents, which were mixed with a spatula. The powder blend wastransferred to a stainless steel screw cap jar, secured in a low shearmixer and tumbled for 10 min at 46 rpm.

Batches were prepared in this way with lactose coated with 1% w/wmenthol, PVP and PG.

Test Formulation 2—Combination of Insoluble APIs Salmeterol Xinafoateand Fluticasone propionate

Salmeterol Xinafoate and Fluticasone propionate were selected as a modelAPI combination to blend with the lactose (coated or uncoated). Lactosewas blended with the APIs so that the final product contained 7.8% and26.9% w/w SX and FP respectively in a 1:8.6 (SX)/1:2.5 (FP):Lactoseformulation and 4.7% and 16.3% w/w SX and FP respectively in a 1:17.2(SX)/5 (FP):Lactose formulation. The target dose was 36.3 μg of SX (25μg salmeterol) and 125 μg of FP per actuation from the valve and 30.5 μg(21 μg salmeterol) SX and 110 μg of FP from the actuator, the meteringvalve volume was 50 μL.

Batch sizes were approximately 4.48 and 4.94 g total powder for 1:8.6(SX)/1:2.5 (FP) and 1:17.2 (SX)/1:5 (FP):Lactose formulationsrespectively. Samples of the coated lactose were blended with the SX:FPby adding discrete amounts of lactose to a glass mortar, and mixing witha spatula at each addition, to ensure geometric dilution of the APIs.The powder blend was transferred to a stainless steel screw cap jar,secured in a low shear mixer and tumbled for 10 min at 46 rpm.

1:8.6 (SX)/1:2.5 (FP) % w/w:Lactose tablets were manufactured usingmenthol coated lactose using a bench top tabletting machine fitted witha punch (upper and lower punch diameter 6 mm) and die (6.0 mm) assembly.Tablets were individually manufactured with uncoated and 1% coatedlactose.

1:17.2 (SX)/1:5 (FP) % w/w:Lactose Tablets were individuallymanufactured with uncoated and 1% coated lactose.

Test Formulation 3—1:5 w/w BDP:Lactose (control, un-coated lactose)

Beclometasone Dipropionate (non-micronised) was selected as a model APIto blend with the lactose both coated or uncoated. Lactose was blendedwith API so that the final product contained approximately 16.7% w/w BDP(approx 1:5 Lactose:BDP). The target dose was 50 μg of BDP peractuation, the metering valve volume was 50 μL.

Batch sizes were approximately 4.35 g total powder. Samples of theuncoated lactose were blended with the BDP by adding discrete amounts oflactose and BDP to a glass mortar, and mixing with a spatula at eachaddition, to ensure geometric dilution of the API. The powder blend wastransferred to a stainless steel screw cap jar, secured in a low shearmixer and tumbled for 10 min at 46 rpm.

1:5 w/w BDP:Lactose compressed dosage forms were manufactured usinguncoated lactose or 1% w/w menthol coated lactose using a bench toptabletting machine fitted with a punch and die assembly designed toproduce 0.6 mm diameter round, flat face, bevelled edged tablets.Tablets were individually manufactured.

1:2 w/w BDP:Lactose was blended with the uncoated lactose so that thefinal product contained approximately 33.3% w/w BDP. Batch sizes wereapproximately 2.18 g total powder. Samples of the uncoated lactose wereblended with the BDP in the same manner described for the 1:5formulations. Coated formulations were repeated with the same bulklactose coated with 1% w/w menthol.

Test Formulation 4—1:12 BDP:Lactose and approx. 1:5 SS:Lactose)

BDP and micronised salbutamol sulphate were blended with uncoatedlactose so that the final product contained approximately 5%, and 12%w/w BDP and SS respectively. Batch sizes were approximately 5.56 g totalpowder. Samples of the uncoated lactose were blended with the SS and BDPby passing through a 90 μm test sieve and transferred to a glass mortarand thoroughly mixed. Thereafter, the remaining uncoated lactose wasadded to the mortar so as to ensure geometric dilution of the mortarcontents, which were mixed with a spatula. The powder blend wastransferred to a stainless steel screw cap jar, secured in a low shearmixer and tumbled for 10 min at 46 rpm.

Content Uniformity

The content uniformity of the powder blends was determined as follows:three samples were randomly taken from the bulk powder blends andaccurately weighed into 100 mL flasks and diluted to volume with HPLCgrade water. Following mixing, 50 μL samples were withdrawn andtransferred to 10 mL volumetric flasks and diluted to volume. SS wasquantified using a validated high performance liquid chromatography(HPLC) method. SX:FP, BDP, BDP/SS were quantified using a validated highperformance liquid chromatography (HPLC) method.

Preliminary Disintegration Tests

Samples of the tablets were individually weighed and dispensed intoglass aerosol vials and 50 μL metering valves were crimped to seal thecontainers. HFA 134a was added in appropriate amounts via the valve andthe weight of propellant dispensed into the can was recorded. In somecases the preparations were sonicated using a sonic bath or placed on amechanical flask shaker. To facilitate more readily dispersedformulations, a ball bearing or plastic pea may be dispensed into thecan during manufacture.

Preliminary Aerosol Testing—Particle Size Distribution

Samples of the tablets prepared using 1% menthol coated lactose andblended with SS were used for aerosol testing. The tablets weredispensed into glass aerosol vials or PET vials, and 19 mL fluorocarbonpolymerised aluminium canisters. 50 μL metering valves were crimped toseal the vials and propellant HFA 134a was filled.

In the case of soluble API formulations, the vial containing the tabletwas placed into a mixture of dry ice/acetone in a Dewar flask along withpre-prepared canister of 5% (w/w) ethanol in HFA 134a propellant. Boththe vial containing tablet and the canister containing the 5% ethanol inpropellant HFA 134a were cooled in the dry ice/acetone mixture for atleast 5 min. The canister of ethanol and propellant was securely clampedand the valve was removed, the contents were carefully poured into thepre-cooled can containing the tablet and the valve was placed on the canand without delay the valve was crimped securely in place.

In addition to the tablet preparations, powder blends (uncompressedcontrols) were investigated. For example, a sample of SS:coated lactoseblend that had not been compressed into a construct, and the second wasan equivalent ratio of SS:lactose in which the lactose had neither beencoated nor compressed into a tablet.

The formulations and the control preparations were tested usingactuators with 0.35 mm orifice diameters unless otherwise stated.

The aerodynamic particle size distribution of the emitted aerosols wasdetermined by inertial impaction testing using a Next GenerationImpactor (NGI) operated at a standard flow rate of 30 L/min. RecoveredAPI samples were quantified by validated HPLC assay. One of the keyaerosol characteristics determined from the NGI tests was the fineparticle fraction (FPF), i.e. the % of the recovered API with anaerodynamic particle size less than 5 μm. It is generally regarded thatparticles with aerodynamic diameters of less than 5 μm will penetrateinto the lower airways. Other key parameters evaluated from the NGIparticle size distribution data were the fine particle dose (FPD) i.e.the amount (μg) of API with an aerodynamic particle size less than 5 μm.

Results

In order to investigate the feasibility of the proposed formulationapproach a series of preliminary experiments were conducted to assesssome of the key variables.

The strategy was to establish the solubility of proposed disintegrantsin propellants HFA 134a and 227. Thereafter samples of lactose werecoated with the most suitable disintegrant materials and compressed intotablets using a bench top tableting machine.

Following these experiments candidate disintegrants were coated ontolactose and blended with a model API i.e. salbutamol sulphate (SS). Thepowder blends were characterised in terms of content uniformity i.e.established that each unit dose of powder contained the calculated doseof SS.

Samples of the SS:coated lactose blends were compressed into tablets anddispensed into canisters and filled with propellant. Control samplesconsisted of the same powder blend dispensed into canisters withoutcompaction into tablets, and also an equivalent SS:lactose blend withnon-coated non-compressed lactose. The aerosol properties of theseformulations were assessed and compared to a reference product i.e.Ventolin® (Evohaler, GSK, UK).

Solubility Results

Table 1 shows the observations relating to visual estimates of thesolubility of glycerol, Tween 80 and PEG 400 in HFA 134a. It wasdetermined that glycerol at a concentration of 0.063% w/w was notsoluble in HFA 134a alone. The other materials at the low concentrationsinvestigated were soluble.

Table 2 shows the observations relating to the solubility of otherpotential disintegrants in propellants 134a and 227. Menthol and PGappeared soluble in both propellants at the concentrations investigated.PVP was observed to be soluble in HFA 227 but not in HFA 134a. PEG 6000,sodium bicarbonate and citric acid were insoluble in both propellants atthe concentrations investigated but are likely to be soluble in ethanolblends of the propellant.

Further solubility tests were performed for Menthol, PVP and PG todetermine solubility at higher concentrations. The results are shown inTable 3.

Lactose Coating

Based on the actual weights of lactose and disintegrant materials usedin the coating process, the concentrations on a % w/w basis for the sixmaterials (i.e. Glycerol, PEG 400, Tween 80, Menthol, PVP and PG)observed to have some solubility in HFA propellants are shown in Table4.

EXAMPLE 1 1.1 Preliminary Tablet Formulation 1—No API

Based on the solubility observations in Table 1, preliminary tabletformulations were prepared using lactose coated with 5% w/w PEG 400, 1%w/w PEG 400, 1% w/w Tween 80 or 1% w/w glycerol. Uncoated lactose wasused a as control.

The 5% PEG 400 formulations had a greater tendency to disintegrate inHFA 134a than the 1% PEG 400, which was more effectively dispersed than1% Tween 80, which in turn was more effectively dispersed than 1%glycerol. Order of disintegration was therefore 5% PEG 400>1% PEG 400>1%Tween>1% glycerol. It was found that although vigorous hand shakingcaused a small amount of dispersion that sonication (or ballbearing/plastic ‘pea’ agitation) was necessary to fully disperse the 5%PEG 400 tablet.

The lactose only formulation showed no sign of dispersion followingprolonged sonication i.e. >15 min. Thus it may be concluded thatdistintegrants were therefore necessary for dispersal of tabletsformulated from lactose alone.

Table 2 showed that menthol, PVP and PG also had some solubility in HFA134a and/or 227. Table 3 showed that the greatest levels of solubilitywere observed for menthol. Tablet formulations were subsequentlyprepared with lactose coated with 1% w/w menthol, PVP, and PG.

The percent of disintegrant as a proportion of the weight of lactosecarrier is shown in Table 4.

1.2 Tablet Formulations with Selected Disintegrants were ReadilyDispersible

Samples of tablets containing lactose coated with 1% menthol wereobserved to be most readily re-dispersed upon addition of HFA 134a.Shaking by hand was sufficient to cause disruption of the dosage formwhile short sonication (3 min) was found to remove visible aggregates.The 1% PVP and PG formulations were not as readily disrupted althoughthe PG dosage form dispersed to a greater extent that the PVP tablet.The formulations were placed on a mechanical flask shaker for 1 h butlarge aggregates remained in the PG and PVP formulations. The vials weresonicated for 3 minutes and the number and size of the aggregates wasreduced, however more and bigger aggregates remained in the PVP samplecompared to the PG sample.

EXAMPLE 2 2.1 Test Formulation 1: Salbutamol Sulphate (SS):CoatedLactose

The formulations were designed to deliver approximately 100 μg ofsalbutamol base from the mouthpiece i.e. to enable comparison with areference product Ventolin® Evohaler (GlaxoSmithKline, UK) i.e. acommercially available form of micronised salbutamol sulphate suspendedin HFA 134a. Ventolin was tested using its standard actuator.

The theoretical concentrations of salbutamol sulphate (SS) in the blendsmanufactured with coated lactose are shown in Table 5. For the controlsample, SS was blended with uncoated lactose. All other samples containthe same batch of lactose following coating with the specifiedadditives.

Table 6 shows the content uniformity for powder blends prepared from SSand coated and uncoated (control) lactose samples. The actual measuredSS content of the blends as determined by HPLC was compared to thetheoretical content determined from the known masses of SS and lactoseused for manufacture. The mean values were all within ±7% of thetheoretical values.

The variability of the measured concentrations were all less than 3% RSDindicating homogeneous distribution of the SS with the lactose.

The same batches of lactose and SS were used for the manufacture of allblends.

2.2 Preliminary Aerosol Characterisation

Samples of tablets prepared from SS blended with lactose coated with 1%w/w menthol were dispensed into aerosol containers and HFA 134a wasadded. For control purposes pMDI were also prepared from a sample of theSS:coated lactose batch that had not been compressed into tablets, and abatch of SS prepared with uncoated lactose that was not compressed intotablets. All batches contained SS at a nominal concentration of 5% w/wrelative to the lactose i.e. 1:20 weight:weight (w/w) SS:lactose.

The constituents of the manufactured pMDI are shown in Table 7.Following manufacture the pMDI vials containing the tablet formulationswith 1% coated menthol were shaken vigorously by hand which causedinitial significant disruption of the tablets. However, on closeinspection some small aggregates were still visible in the pMDI vials,consequently the vials were sonicated for 3×3 min which appeared toeffectively disrupt the aggregates. No such aggregates were observed forthe two control formulations.

Initial testing of the samples indicated that there was a propensity forthe valve stem/actuator of the pMDI to block after a small number ofactuations.

However, the properties of the emitted aerosol were well suited toinhalation therapy with 42% of the emitted SS recovered in therespirable range i.e. <5 μm aerodynamic diameter (Table 8). In terms ofFPF (43%) the performance of the control formulations prepared fromcoated lactose was very similar to the novel formulation approach.

The mean emitted doses for the novel formulation and the uncoatedlactose control were close to the theoretical values. The SS recoveryfrom the coated lactose control was greater than the theoretical value.

The recovery of SS and the deposition pattern of SS in the NGI for thetest formulation (compressed SS:menthol coated lactose), the controlformulations (uncompressed SS:menthol coated lactose, andSS:uncompressed, uncoated lactose) and the reference product (Ventolin®Evohaler) are shown in Table 9 and FIG. 1.

Ventolin® Evohaler was tested alongside the novel formulation andcontrol samples. In general there was good agreement between the FPF andFPD for test and reference products. The API recovery from the InductionPort and Stage 1 for the novel formulation was close to that recoveredfrom the Induction Port for the Ventolin® reference product. Thefraction of API recovered from Stages 4, 5 and 6 for the novelformulation showed a similar distribution to that of the Referenceproduct.

EXAMPLE 3

3.1 Test Formulation 2—Salmeterol Xinafoate and Fluticasone propionate

Propellant disintegratable compressed dosage forms (tablets) containinga combination of two propellants (where propellant is specified earlieras being a blend or contain ethanol or other acceptable excipients),insoluble API's namely, fluticasone propionate (FP) and salmeterolxinafoate (SX), were prepared and used to formulate pressurized metereddose inhalers. Such combinations of a bronchodilator and ananti-inflammatory agent are commonly used in the therapy of asthma andCOPD.

The formulations were designed to deliver approximately 36.3 μg of SXand 125 μg of FP per metered dose (120 doses) i.e. to be comparable withthe Seretide® Evohaler® (Reference product, Glaxo Wellcome UK Limited,UK) a commercially available suspension form of salmeterol xinafoate andfluticasone propionate in HFA 134a. Seretide was tested using itsstandard actuator.

The theoretical concentrations of SX and FP in the blends manufacturedwith coated lactose are shown in Table 10. For the control sample SX andFP was blended with uncoated lactose.

Tables 11 and 12 show the content uniformity for powder blends preparedfrom SX:FP and coated and uncoated lactose samples. The actual measuredSX:FP content of the blends as determined by HPLC was compared to thetheoretical content determined from the known masses of SX:FP andlactose used for manufacture. The mean values were all within ±4% of thetheoretical values.

The variability of the measured concentrations were all less than 3% RSDindicating homogeneous distribution of the SX:FP with the lactose.

The same batches of lactose, SS and FP were used for the manufacture ofall blends.

3.2 Preliminary Tablet Characterisation

For the 1:8.6 (SX)/1:2.5 (FP) blends typical tablet weights were between0.0633-0.0793 g for uncoated and 1% coated lactose formulations. Thefinal theoretical menthol concentration in the pMDI canisters was from0.0077-0.0083% w/w for 1% w/w menthol coated lactose formulations.Further details of these formulations are shown in Table 13.

For the 1:17.2(SX)/1:5(FP) blends typical tablet weights were between0.1126-0.1227 g for uncoated and 1% coated lactose formulations. Thefinal theoretical menthol concentration in the pMDI canisters was0.0131-0.0137% w/w for 1% w/w menthol coated lactose formulations.Further details of these formulations are shown in Table 14.

3.3 Preliminary Aerosol Characterisation

Tables 15 and 16 show the dose characteristics for salmeterol andfluticasone respectively for formulations prepared from a blend of APIand lactose with the following weight ratios 1: 8.6 SX:lactose and 1:2.5FP:lactose. Two control formulations were assessed, i.e. tabletsprepared with uncoated lactose and also powder blends that were notcompressed into tablets.

In general the tablets with lactose coated with disintegrant were moreeasily dispersed in the propellant than the un-coated control tablets.The control tablets even after hand shaking/mechanical shaking andsonication contained large agglomerates of powder.

Tables 15 and 16 show that the aerosol and dose characteristics i.e. FPFand FPD for both the SX and FP were in good agreement with the referenceproduct (Seretide). The metered doses for these non-optimised novelformulations were also in line with the reference product.

The characteristics determined for the 1:8.6 SX:1:2.5 FP:lactoseformulations were also observed for the 1:17.2 SX:1:5 FP:lactoseformulations. Tables 17 and 18 summarise the aerosol and dosecharacteristics, the fine particle fractions and the fine particle dosesdelivered via the construct formulations compared favourably with theReference Product.

EXAMPLE 4 4.1 Test Formulation—Soluble API Beclometasone Dipropionate

Propellant disintegratable compressed dosage forms (tablets) containinga soluble API namely, Beclometasone Dipropionate (BDP), was prepared andused to formulate pressurized metered dose inhalers.

The formulations were designed to deliver approximately 50 μg of BDP permetered dose (200 doses) i.e. to be comparable with the QVAR® (Referenceproduct, Teva UK Limited, UK) a commercially available solution form ofbeclomethasone dipropionate in HFA 134a. QVAR® was tested using itsstandard actuator.

Inspection of Table 19 illustrates the uniformity of the BDP:Lac powderblends. The RSD values of the powder blends were below 2% for allformulations. The BDP recoveries from the powder blends of the 1:2coated and the 1:5 uncoated were approximately 112 and 85% respectivelyof the target. In the preparation of pMDI from these powder blends themass of propellant added to the canisters was adjusted so as to provide50 μg per actuation of BDP.

Typical construct weights for the 1:5 w/w BDP:Lactose blends were in therange 0.066-0.084 g. For the 1:2 w/w BDP:Lactose blends tablet weightsranged from 0.0401-0.0504 g.

4.2 Preliminary Aerosol Characterisation

BDP has a degree of solubility in HFA 134a, the extent of which makessuspension systems untenable due to the potential for API dissolutionand subsequent crystal growth leading to unstable suspension systems.However, the addition of a small quantity of ethanol i.e. approx. 5% w/wis adequate to ensure sufficient solubility of BDP for at least 50μg/actuation solution systems.

The dose characteristics and aerosol properties using an actuator with a0.4 mm orifice diameter are shown in Table 20. Inspection of the PETvials for the BDP alone control formulation showed a clear solutionindicating that the BDP was dissolved in the 5% w/w ethanol:HFA medium.For all formulations the majority of the BDP in the NGI (i.e. that notimpacted in the Induction Port) was deposited on stages with effectivecut-off diameters of less than 2.3 μm, with significant deposition belowthe micro-orifice collector (MOC<0.54 μm). This type of depositionpattern is indicative of an API being dissolved in the propellantsystem.

The dose characteristics and aerosol data shown in Table 21 weregenerated using the same pMDI units described above. However for thesetests a 0.25 mm orifice diameter actuator was used. Consequently a finerand slower moving aerosol plume was generated i.e. reduced ballisticimpaction. The aerodynamic particle size distribution of the novelformulations was shifted towards the right and was more closely alignedwith that of the Reference product. Key aerosol parameters demonstratethis, in particular the FPF increased to match or exceed the Referenceproduct.

Overall this provides proof of concept that following blending,non-micronised soluble API and lactose (coated and uncoated), can becompressed into tablet form and dispersed in a propellant systemincorporating a co-solvent e.g. HFA 134a/ethanol blend, in which thesoluble API subsequently dissolved. The dose properties and aerosolcharacteristics of the formulations were shown to compare favourablywith marketed reference products.

EXAMPLE 5 5.1 Test Formulation—Combination Soluble and Insoluble API

Soluble APIs may also be formulated in combination systems withinsoluble suspended API, this is exemplified by the solution/suspensioncombination formulation of salbutamol sulphate (SS) and beclometasonedipropionate (BDP) where SS is in suspension and BDP is in solution.

Inspection of Table 22 illustrates the uniformity of the BDP/SS:Lacpowder blends. The RSD values of the powder blends were below 2% for allformulations. Typical tablet weights were between 0.1771-0.1999 g and0.0862-0.1038 g for uncoated and coated tablets respectively.

5.2 Preliminary Aerosol Characterisation

The dose characteristics and aerosol properties are shown in Tables 23and 24.

The BDP data (Table 23) i.e. soluble API, show similar aerodynamicparticle size distributions as QVAR®, resulting in fine particlefraction (range 70.70 81.12%<5 μm) values similar to the Referenceproduct (72.96%<5 μm). The fine particle doses (range 32.26-35.74 μg)were also similar to that of QVAR® (26.54 μg).

Salbutamol sulphate data i.e. the suspended API, are shown in Table 24.Ventolin Evohaler (GSK) and Airomir (Teva) were assessed as theReference products. Neither Reference formulation was an exact match forthe Test formulation in that Ventolin does not contain any ethanol orother excipients, however the volume of the metered dose i.e. 50 μLmatches that of the Test formulations. Whilst Airomir does containethanol it also has a surfactant (oleic acid) and utilises a smallervalve metering chamber (25 μL).

Table 24 shows the metered doses (emitted doses) per actuation for thesenon-optimised formulations.

In general the fine particle fraction data (range 43.02-54.62%<5 μm)matched or exceeded those of the Reference products (range36.01-48.80%<5 μm). As a consequence of the metered (emitted) doseexceeding the target the fine particle mass was also superior to theReference products.

When actuated through a 0.25 mm diameter actuator orifice the aerosol soformed had characteristics similar to those observed for the twomarketed products tested individually.

Summary

Experiments to investigate the disintegration, in propellant HFA 134a,of tablets formed by the direct compression of lactose showed poordispersion of the tablets. Consequently the solubility of a range ofcompounds identified as possible disintegrants i.e. materials to beincluded in the tablet that would promote dispersion in HFA propellants,were evaluated.

A range of materials i.e. glycerol, PEG 400, Tween 80, PVP and PG,showed limited solubility (approx. range 0.05-0.1% w/w) in HFApropellants. Menthol, in contrast was found to be soluble atconcentrations of approx.≤3% w/w in HFA 134a and 227.

Samples of lactose were coated with selected disintegrants atconcentrations of either 1 or 5% w/w.

Since menthol showed the greatest solubility in the propellant this wasidentified as the material most likely to enhance disintegration of thecompressed dosage forms.

Consequently menthol coated lactose was blended with a model API (SS)and compressed into tablets, dispensed into aerosol cans and meteringvalves crimped to seal the cans. Upon addition of propellant HFA 134a tothe aerosol container the tablets were observed to disperse primarily byhand shaking, although ball bearings/plastic ‘peas’ or sonication wasrequired to disrupt some small aggregates.

Following dispersion of the tablet the resulting suspension systemwithin the aerosol container was expected to demonstrate similarproperties to formulations described in the original PCT filing (3).

The key aerosol characteristics of this non-optimised test formulationcompared favourably with the reference product (Ventolin® Evohaler). Theconcentration of menthol in terms of the propellant was very low i.e.approx. 0.4% % w/w (Table 7) thus it is anticipated that increasing theamount of menthol associated with the lactose may improve disintegrationof the tablet. Solubility results show that the menthol concentrationcould be increased several-fold (see Table 3).

Additionally, it has been shown that both soluble and insoluble APIs canbe prepared and delivered in this way.

Further, it has been shown that a combination of APIs can be effectivelyprepared and delivered and a dose equivalent to or greater than existingsystems. This is particularly advantageous as it permits delivery ofmultiple therapeutics in a single controlled dose.

Additionally, it has been shown that two API's with differingphysicochemical properties (i.e. micronised versus non-micronised) anddiffering therapeutic targets (i.e. anti-inflammatory versusbronchodilator) can be successfully blended together and compressed intoa tablet, and importantly, dispersed without the need for mechanicalshaking or sonication. Additionally, formulations prepared withoutdisintegrant were also shown to disperse and the suspension/solutionsystems so formed demonstrated acceptable aerosol properties. Thisprovides the ability to prepare both soluble and insoluble APIs in thepreparation of pMDIs which previously proved troublesome.

Consequently, the technique disclosed herein could potentially greatlysimplify the filling process by removing the requirement to performcomplex pressurized single stage fills i.e. re-cycling homogenisedsuspension of micronised API at high pressures. Also steps such asdetermining when the pressure vessel required topping up with propellant(to account for evaporation into the head space) and samplingre-circulating suspension to determine API levels would become obsolete.

REFERENCES

To be completed based on those references retained above.

-   -   1. U.S. Pat. No. 5,776,432.    -   2. WO 98/56349    -   3. WO 99/51205    -   4. WO 2008/053250

TABLE 1 Conc. Wt of Additive Material Wt 134a (% w/w) Soluble VialMaterial (g) (g) 134a (Y/N/) 1 Glycerol 0.00090 10.5334 0.009 Y 2Glycerol 0.0067 10.5727 0.063 N 3 Tween 80 0.00097 10.5842 0.009 Y 4Tween 80 0.0083 10.5607 0.079 Y 5 PEG 400 0.0099 10.5703 0.094 Y 6 PEG400 0.0055 10.6284 0.052 Y

TABLE 2 Conc. Wt of Additive Material Wt HFA (% w/w) in Soluble VialMaterial (g) (g) Propellant (Y/N) *1 Menthol 0.0051 11.7946 0.0432 Y *2Menthol 0.0174 11.9227 0.1457 Y *3 PVP 0.0062 11.9582 0.0518 Y *4 PEG6000 0.0103 12.0205 0.0856 N *5 Na Bicarbonate 0.0040 11.7518 0.0340 N*6 Citric Acid 0.0091 11.9981 0.0758 N *7 PG 0.0098 11.5224 0.0850 Y^(#)8 Menthol 0.0070 10.7485 0.0651 Y ^(#)9 PVP 0.0063 10.8160 0.0582 N^(#)10 PEG 6000 0.1020 10.7120 0.9432 N ^(#)11 Na Bicarbonate 0.006610.9173 0.0604 N ^(#)12 Citric Acid 0.0071 10.9377 0.0649 N ^(#)13 PG0.0093 10.9534 0.0848 Y

TABLE 3 Conc. Material Wt of Additive Descrip- Material Wt HFA (% w/w)Vial tion (g) (g) 134a Observations *1 Menthol 0.0941 9.8298 0.9482Soluble *2 Menthol 0.3076 9.9939 2.9860 Insoluble, thin crystals atinterface adhering to vial *3 PVP 0.0977 9.8169 0.9854 Insoluble, wettedmaterial creamed at interface *4 PVP 0.2768 9.9776 2.6993 As above *5 PG0.0974 9.7900 0.9851 Insoluble droplets adhering to sides of vial *6 PG0.2930 10.0344 2.8371 As above #7 Menthol 0.1014 9.4114 1.0659 Soluble#8 Menthol 0.3233 8.7691 3.5557 Insoluble, long thin needle likecrystals #9 Menthol 0.5103 7.7642 6.1671 As above #10 PVP 0.1100 9.55861.1377 Insoluble, particles, tending to floculate #11 PVP 0.2971 7.27893.9216 As above #12 PG 0.1011 18.1890 0.5528 Insoluble, droplets atinterface #13 PG 0.2966 9.7761 2.9446 As above #14 PG 0.4980 9.93614.7728 As above

TABLE 4 Target Actual Conc. Glycerol PEG Tween Menthol Lactose Conc. (%w/w) (g) 400 (g) 80 (g) (g) PVP (g) PG (g) (g) (% w/w) 1% 0.2014 — — — —— 19.8000 1.02 5% 1.0167 — — — — — 19.0453 5.34 1% — 0.2004 — — — —19.8146 1.01 5% — 1.0030 — — — — 19.0000 5.28 1% — — 0.2070 — — —19.8300 1.04 5% — — 0.9919 — — — 19.0074 5.22 1% — — — 0.1996 — —19.8010 1.00 1% — — — — 0.2009 — 19.8022 1.00 1% — — — — 0.2025 19.80681.0

TABLE 5 Blend Details SS (g) Lactose (g) % SS (w/w) 1% Menthol 0.47288.9939 4.99 1% PG 0.4729 8.9947 4.99 1% PVP 0.4723 9.0001 4.99 Lactose(Control) 0.4725 9.0008 4.99

TABLE 6 Formulation Sample Mass Theoretical Actual % Details (g) SS (g)SS (g) Theoretical 1% Menthol 0.1987 0.0099 0.0095 95.81 (Coated 0.17110.0085 0.0083 97.04 Lactose) 0.1985 0.0099 0.0100 100.90 Mean 97.92 SD2.65 RSD 2.71 1% PG 0.1917 0.0096 0.0097 101.51 (Coated 0.2039 0.01020.0103 101.16 Lactose) 0.2139 0.0107 0.0112 104.49 Mean 102.39 SD 1.83RSD 1.79 1% PVP 0.2068 0.0103 0.0100 96.44 (Coated 0.2216 0.0111 0.011099.01 Lactose) 0.2476 0.0124 0.0122 98.56 Mean 98.00 SD 1.37 RSD 1.40Control 0.3041 0.0152 0.0166 109.25 (Uncoated 0.3157 0.0157 0.0165104.72 Lactose) 0.3065 0.0153 0.0166 108.31 Mean 107.43 SD 2.39 RSD 2.23

TABLE 7 Conc. Lac Conc. Vial Formulation Wt of Wt Total Wt of Filled (%w/w) Menthol (% Number Description tablet (g) 134a (g) Formulation (g)134a w/w) 134a *1 1% Menthol - Tab 0.3295 9.1730 9.5029 3.4675 0.0358 *21% Menthol - Tab 0.4299 9.1532 9.5833 4.4860 0.0468 *3 1% Menthol - Tab0.3907 9.2909 9.6821 4.0355 0.0419 ^(#)4 Control 1% Menthol 0.35189.3789 9.3785 3.6154 0.0374 ^(#)5 Control 1% Menthol 0.3391 9.55339.5530 3.4279 0.0354 ^(#)6 Control 1% Menthol 0.4333 9.5715 9.57114.3309 0.0452 ^(§)7 Control Lac 0.3025 9.4364 9.4361 3.1061 — ^(§)8Control Lac 0.3062 9.3829 9.3826 3.1603 — ^(§)9 Control Lac 0.41259.4851 9.4847 4.1677 —

TABLE 8 *1% ^(#)1% Menthol Menthol ^(§)Lactose Ventolin ® FormulationTablet Control Control Evohaler Metered (Shot) 82.10 69.38 65.78 0.07Weight (mg) Metered Dose/Actuation N/D 179.71 132.39 N/D inc. Actuator(μg) Emitted SS Per Actuation 118.78 148.74 108.98 99.67 (ex Actuator)(μg) SS FPF (% < 5 μm) 42.26 43.28 35.66 49.35 SS FPD (μg < 5 μm) 50.2064.37 38.86 40.82 (ex device)

TABLE 9 ^(#)1% Ventolin ® *1% Menthol ^(§)Lactose Evohaler FormulationMenthol Control Control Reference Induction Port 22.13 23.08 23.70 45.37Stage 1 (ECD = 11.72 μm) 25.62 24.07 33.25 1.73 Stage 2 (ECD = 6.4 μm)5.48 4.47 3.97 1.49 Stage 3 (ECD = 3.99 μm) 8.69 9.89 6.54 4.66 Stage 4(ECD = 2.3 μm) 15.31 17.96 13.73 17.75 Stage 5 (ECD = 1.36 μm) 13.9712.63 10.69 18.81 Stage 6 (ECD = 0.83 μm) 5.50 5.45 5.12 7.43 Stage 7(ECD = 0.54 μm) 2.56 1.92 2.14 2.06 MOC 0.74 0.53 0.87 0.69

TABLE 10 SX FP Lactose % SX % FP Blend Details (g) (g) (g) (w/w) (w/w)1:8.6 (SX)/ 0.3498 1.2051 2.9227 7.81 26.91 2.5 (FP):Coated Lactose1:17.2 (SX)/ 0.2332 0.8030 3.9039 4.72 16.25 5 (FP):Coated Lactose

TABLE 11 Formulation Sample Theoretical Actual Theoretical Details Mass(g) API (mg) API (mg) (%) 1:8.6 0.0739 5.6546 5.4381 96.17(SX)/:Un-coated 0.0739 5.6546 5.6259 99.49 Lactose 0.0739 5.6546 5.570798.82 Mean 98.06 SD 1.71 RSD 1.74 1:2.5 0.0739 19.4897 19.0798 97.85(FP):Un-coated 0.0739 19.4987 19.6694 100.88 Lactose 0.0739 19.498719.5955 100.50 Mean 99.74 SD 1.65 RSD 1.65 1:8.6 0.0739 5.6546 5.578898.66 (SX)/:1% 0.0739 5.6546 5.6090 99.19 coated 0.0739 5.6546 5.589998.86 Lactose Mean 98.90 SD 0.27 RSD 0.27 1:2.5 0.0739 19.4897 19.5370100.20 (FP):1% 0.0739 19.4987 19.4349 99.67 coated 0.0739 19.498719.9922 102.53 Lactose Mean 100.80 SD 1.52 RSD 1.51

TABLE 12 Formulation Sample Theoretical Actual Theoretical Details Mass(g) SS (mg) SS (mg) (%) 1:17.2 0.1227 5.6571 5.5221 97.61(SX)/:Un-coated 0.1227 5.6571 5.6826 100.45 Lactose 0.1227 5.6571 5.609999.17 Mean 99.08 SD 1.42 RSD 1.43 1:5 0.1227 19.5072 19.3246 99.06(FP):Un-coated 0.1227 19.5072 19.9174 102.10 Lactose 0.1227 19.507219.8502 101.76 Mean 100.98 SD 1.66 RSD 1.65 1:17.2 0.1227 5.6571 5.6976100.72 (SX)/:1% 0.1227 5.6571 5.7033 100.82 coated 0.1227 5.6571 5.6813100.43 Lactose Mean 100.65 SD 0.20 RSD 0.20 1:5 0.1227 19.5072 20.1627103.36 (FP):1% 0.1227 19.5072 20.1625 103.36 coated 0.1227 19.507220.2293 103.70 Lactose Mean 103.47 SD 0.20 RSD 0.19

TABLE 13 Total wt of Conc. Filled Conc. Lac Menthol Formulation Wt of Wt134a Formulation (% (% w/w) Vial Description Tablet (g) (g) (g) w/w)134a134a 1* 1:8.6(SX)/2.5(FP): 0.0793 9.2047 9.2840 0.85 Un-coated LactoseTab 2* 1:8.6(SX)/2.5(FP): 0.0633 9.0227 9.0860 0.70 Un-coated LactoseTab 3* 1:8.6(SX)/2.5(FP): 0.0657 9.0526 9.1183 0.72 Un-coated LactoseTab 4^(#) 1:8.6(SX)/2.5(FP): 1% 0.0703 9.2559 9.3262 0.75 0.0077 MentholTab (Coated Lactose) 5^(#) 1:8.6(SX)/2.5(FP): 1% 0.0726 9.0401 9.11270.80 0.0081 Menthol Tab (Coated Lactose) 6^(#) 1:8.6(SX)/2.5(FP): 1%0.0702 9.0305 9.1007 0.77 0.0079 Menthol Tab (Coated Lactose) 7^(¥)1:8.6(SX)/2.5(FP): 1% 0.0738 9.0342 9.1080 0.81 0.0083 Menthol Cont(Coated Lactose) 8^(¥) 1:8.6(SX)/1:2.5(FP): 0.0738 9.0285 9.1023 0.810.0083 1% Menthol Cont (Coated Lactose 9^(¥) 1:8.6(SX)/1:2.5(FP): 0.07389.0536 9.1274 0.81 0.0082 1% Menthol Cont (Coated Lactose

TABLE 14 Total wt of Conc. Wt of Filled Conc. Lac Menthol VialFormulation Tablet Wt 134a Formulation (% (% w/w) Number Description (g)(g) (g) w/w)134a 134a 1* 1:17.2(SX)/1:5(FP): 0.1171 9.2829 9.4000 1.25Un-coated Tab 2^(#) 1:17.2(SX)/1:5(FP): 0.1195 9.2352 9.3547 1.28 0.01311% Menthol Tab (Coated Lactose) 3^(¥) 1:17.2(SX)/1:5(FP): 0.1227 9.05689.1795 1.34 0.0137 1% Menthol Cont (Coated Lactose) 4^(¥)1:17.2(SX)/1:5(FP): 0.1226 9.0542 9.1768 1.34 0.0137 1% Menthol Cont(Coated Lactose) 5^(¥) 1:17.2(SX)/1:5(FP): 0.1126 9.1201 9.2427 1.330.0136 1% Menthol Cont (Coated Lactose)

TABLE 15 1% Menthol Uncoated 1% Menthol Uncompressed Seretide TabletTablet Control Evohaler ® Metered (shot) 65.36 ± 2.73 64.34 ± 1.66 65.23± 0.49 72.92 ± 0.18 Weight (mg) Metered Dose/Actuation 47.04 ± 5.6837.47 ± 3.37 38.90 ± 2.93 33.94 ± 4.06 inc. Actuator (μg) EmittedSX/Actuation 42.90 ± 6.36 33.52 ± 2.65 35.97 ± 2.69 28.96 ± 2.87(ex-Actuator) (μg) SX FPF (% < 5 μm) 46.26 ± 1.83 64.09 ± 3.79 62.02 ±0.19 53.27 ± 3.78 SX FPD (μg < 5 μm) 19.92 ± 3.63 21.54 ± 2.88 22.31 ±1.67 15.40 ± 1.37

TABLE 16 1% Menthol Uncoated 1% Menthol Uncompressed Seretide TabletTablet Control Evohaler ® Metered (shot) 65.36 ± 2.73 64.34 ± 1.66 65.23± 0.49 72.92 ± 0.18 Weight (μg) Metered Dose/Actuation 160.74 ± 15.91132.71 ± 11.38 139.02 ± 10.84 131.14 ± 17.69 inc. Actuator (μg) EmittedFP/Actuation 146.61 ± 18.50 118.44 ± 8.90  128.36 ± 9.89  112.34 ± 12.26(ex-Actuator) (μg) FP FPF (% < 5 μm) 47.77 ± 1.33 63.20 ± 3.69 62.48 ±0.87 53.18 ± 4.17 FP FPD (μg < 5 μm)  70.20 ± 10.66 75.05 ± 9.69 80.13 ±5.11 59.54 ± 4.99

TABLE 17 1% Menthol Uncoated 1% Menthol Uncompressed Seretide TabletTablet Control Evohaler ® Metered (shot) 65.64 70.30 64.57 ± 0.63 72.92± 0.18 Weight (μg) Metered 40.51 40.49 45.03 ± 0.44 33.94 ± 4.06Dose/Actuation inc. Actuator (μg) Emitted 34.66 37.60 41.48 ± 0.47 28.96± 2.87 SS/Actuation (ex-Actuator) (μg) SX FPF (% < 5 μm) 50.53 56.8654.68 ± 1.48 53.27 ± 3.78 SX FPD (μg < 5 μm) 17.51 21.38 22.68 ± 0.6015.40 ± 1.37

TABLE 18 1% Menthol Uncoated 1% Menthol Uncompressed Seretide TabletTablet Control Evohaler ® Metered (shot) 65.64 70.30 64.57 ± 0.63 72.92± 0.18 Weight (mg) Metered 141.94 144.13 159.23 ± 0.86  131.14 ± 17.69Dose/Actuation inc. Actuator (μg) Emitted 121.38 133.84 146.50 ± 1.36 112.34 ± 12.26 SS/Actuation (ex-Actuator) (μg) FP FPF (% < 5 μm) 50.5154.68 53.22 ± 1.52 53.18 ± 4.17 FP FPD (μg < 5 μm) 61.31 73.18 77.96 ±1.94 59.54 ± 4.99

TABLE 19 1:2 - 1:5 - 1:2 - BDP:Lac 1% 1:5 - BDP:Lac 1% Sample BDP:LacMenthol BDP:Lac Menthol Number Uncoated Coated Uncoated Coated 1 102.38111.92 85.90 100.23 2 99.57 112.66 86.54 97.69 3 103.41 109.90 83.81101.23 MEAN 101.79 111.49 85.42 99.72 SD 1.99 1.43 1.43 1.83 RSD 1.951.28 1.67 1.83

TABLE 20 BDP only 1:5 Control 1:5 1% Menthol 1:5 Control 1:5 1% MentholQVAR ® Control Powder Powder Tablet Tablet Mean Metered (Shot) 63.8262.12 63.14 62.94 61.50 60.35 Weight (mg) Metered Dose 71.44 61.66 66.2853.14 56.17 43.99 BDP/Actuation inc. Actuator (μg) Emitted Dose 63.9055.37 58.63 48.07 49.27 36.35 BDP/Actuation (ex Actuator) (μg) BDP FPF(% < 5 μm) 40.28 41.61 41.55 44.33 42.89 72.96 BDP FPD (μg < 25.74 23.0424.36 21.31 21.13 26.54 5 μm) (ex device)

TABLE 21 *1:5 *1:5 1% 1:5 BDP Control Menthol Control QVAR ® only PowderPowder Tablet Mean Metered (Shot) 62.82 61.66 61.60 62.94 60.35 Weight(mg) Metered Dose 66.98 56.42 65.95 58.33 43.99 BDP/Actuation inc.Actuator (μg) Emitted Dose 62.17 52.94 58.83 54.22 36.35 BDP/Actuation(ex Actuator) (μg) BDP FPF (% < 5 μm) 79.49 82.15 67.72 80.86 72.96 BDPFPD (μg < 5 μm) 49.42 43.48 39.84 43.85 26.54 (ex device)

TABLE 22 1:12/(1:5) - 1:12/(1:5) - BDP/SS:Lactose BDP/SS:Lactose 1%UnCoated Menthol Coated Sample Number SS BDP SS BDP 1 94.93 87.11 96.4192.23 2 95.46 90.00 99.00 92.69 3 95.78 88.05 97.52 92.61 Average 95.3988.38 97.64 92.51 SD 0.43 1.48 1.30 0.24 RSD 0.45 1.67 1.33 0.26

TABLE 23 Uncoated 1% Menthol Uncoated Uncoated 1% Menthol 1% MentholCanister Number Powder Coated Powder Tablet Tablet Coated Tablet CoatedTablet QVAR ®Mean Metered (Shot) Weight 62.3 62.3 60.9 63.4 60.3 61.660.35 (mg) Metered Dose BDP/ 47.11 49.57 46.43 48.71 51.01 47.22 43.99Actuation inc. Actuator (μg) Emitted Dose BDP/ 44.23 45.62 43.92 45.3347.55 43.62 36.35 Actuation (ex Actuator) (μg) BDP FPF (% < 5 μm) 75.2070.70 81.12 78.85 70.47 68.90 72.96 BDP FPD (μg < 5 μm) 33.26 32.2635.63 35.74 33.51 30.06 26.54 (ex device) % of BDP on Actuator 6.11 7.965.41 6.94 6.80 7.61 NR

TABLE 24 1% Menthol Uncoated 1% Menthol 1% Menthol Uncoated CoatedTablet Uncoated Coated Tablet Coated Ventolin ® Airomir ® CanisterNumber Powder Powder F12 Tablet F13 F12 TabletF13 SS Mean SS MeanMetered (Shot) Weight (mg) 62.3 62.3 60.9 63.4 60.3 61.6 74.35 31.52Metered Dose SS/Actuation 142.60 165.49 168.89 157.63 155.91 160.25131.11 122.30 inc. Actuator (μg) Emitted Dose SS/Actuation 119.62 151.23157.97 147.14 144.04 148.51 113.53 95.59 (ex Actuator) (μg) SS FPF (% <5 μm) 49.25 43.02 54.62 52.16 50.26 48.47 36.01 48.80 SS FPD (μg < 5 μm)(ex 58.91 65.06 86.28 76.74 72.39 71.98 40.95 46.54 device) % of SS onActuator 16.11 8.61 6.47 6.66 7.61 7.33 13.41 21.84

1. A tablet for use in the manufacture of a pressurized metered doseinhaler (pMDI) comprising: i) a selected amount of at least one activepharmaceutical ingredient (API); ii) a disintegrant that is soluble in aliquid phase; and iii) optionally, at least one excipient.
 2. The tabletaccording to claim 1 wherein said at least one API is a micronised API.3. The tablet according to claim 1 wherein said at least one API is arespiratory therapeutic.
 4. The tablet according to claim 3 wherein saidat least one API is for treating one or more of the following diseasesor conditions: asthma, bronchitis, COPD, chest infections, acute painrelief, migraine, disorders of hormonal imbalance and cardiovasculardisease.
 5. The tablet according to claim 1 wherein said liquid phase isa propellant.
 6. The tablet according to claim 5 wherein said propellantis a hydrocarbon selected from the group consisting of: ahydrofluoroalkane (HFA), HFA 134a (tetrafluorethane), HFA 227ea(heptafluoropropane) a hydrofluoroolefin and mixtures thereof.
 7. Thetablet according to claim 1 wherein said disintegrant is selected fromthe group consisting of: menthol, propylene glycol (PG),polyvinylpolypyrrolidone (PVP), polyethylene glycol (PEG), glycerol,sodium bicarbonate, citric acid and a non-toxic essential oil.
 8. Thetablet according to claim 1 wherein said at least one excipient is aparticulate carrier material.
 9. The tablet according to claim 8 whereinsaid at least one excipient is a particulate carrier material having asize range between range 15 μm-200 μm.
 10. The tablet according to claim1 wherein said at least one excipient is a carbohydrate selected fromthe group consisting of: mono, di, tri, oligo, polysaccharide and anyphysiologically acceptable derivative, salt, solvate thereof and anymixtures thereof; or an amino acid selected from the group comprising:di-, tri-, oligo-, polypeptide, protein and any physiologicallyacceptable derivative, salt, solvate thereof and mixtures thereof. 11.The tablet according to claim 1 wherein said at least one excipient iscoated with said disintegrant.
 12. The tablet according to claim 10wherein said at least one excipient is lactose or leucine.
 13. Thetablet according to claim 11 wherein said at least one excipient iscoated with a disintegrant selected from the group consisting of:menthol, propylene glycol (PG), polyvinylpolypyrrolidone (PVP),polyethylene glycol (PEG), glycerol, sodium bicarbonate, citric acid anda non-toxic essential oil.
 14. The tablet according to claim 13 whereinsaid at least one excipient is lactose or leucine and said disintegrantis menthol or PG.
 15. The tablet according to claim 1 wherein said atleast one excipient is lactose and said disintegrant is menthol.
 16. Thetablet according to claim 1 wherein said at least one API is soluble inthe liquid phase.
 17. The tablet according to claim 1 wherein said atleast one API is insoluble in the liquid phase.
 18. The tablet accordingto claim 1 wherein said tablet comprises a plurality of APIs.
 19. Thetablet according to claim 1 wherein said tablet comprises one or moreAPI(s) soluble in the liquid phase and one or more API(s) insoluble inthe liquid phase.
 20. The tablet according to claim 1 wherein saiddisintegrant is coated onto said one or more APIs.